4 days (Fig. 4 and Table 1). In contrast, all mice immunized with the ΔyscN strain had at least a significant increase in the survival curves (Table 1). An increase in the CFU immunization dose resulted in increased protection was obtained. For those mice that received the 104 dose and higher, the percentage of surviving animals was significantly higher than the control group. Likewise, the mean TTD for Rapamycin in vitro those mice immunized at these higher CFU doses that did succumb to infection was significant in comparison with the control group. The one exception to this was the death of one animal in the 107 group. This mouse
was not representative of the general trend, as the death occurred 1 day postchallenge. Overall, the results show a general increase in protection with the inoculation dose and clearly demonstrate a potential role for the ΔyscN strain as a live plague vaccine. Both the F1 and LcrV proteins have been shown
to mediate immune protection against Y. pestis infection (Anderson et al., 1996; Quenee et al., 2008). The F1 capsule protein, encoded by caf1, is neither a component of the T3SS nor requires the YscN ATPase for secretion. Peptide 17 manufacturer Quantitative anti-F1 and V IgG ELISAs of sera from vaccinated animals were performed from the animals described in the study above. From this analysis, the sera showed an increase in anti-F1 antibodies but only displayed background levels of anti-LcrV antibodies across the inoculation dose (Table 2). The background response to LcrV cannot be explained by low immunogenicity of the protein, as elevated levels of LcrV antibodies are present in animals exposed to Y. pestis (Benner et al., 1999). Our results from the dot blot assay (Fig. 2) and the ELISAs (Table 2) demonstrate clearly that the LcrV protein was not secreted by the ΔyscN mutant of Y. pestis. The Y. pestis T3SS has been described heptaminol in detail, and its major features are well known (Cornelis, 2002a, b; Viboud & Bliska, 2005). The delivery of Yop effectors
requires an active ATPase, and removal of its ability to hydrolyze ATP prevents the delivery of virulence factors in the highly homologous Y. enterocolitica (Blaylock et al., 2006) or the more distant enteropathogenic Escherichia coli (Zarivach et al., 2007). YscN is the only T3SS system ATPase in Y. pestis and disabling its ability to hydrolyze ATP is a potential strategy for inactivating a major virulence factor. The YscN protein has no significant homology to human proteins (< 20% identity, W. Swietnicki, unpublished data). Therefore, targeting the YscN protein potentially offers a selective means for inhibiting the Y. pestis T3SS without interfering with host ATPases. We demonstrated that an internal nonpolar deletion of the yscN gene in a fully virulent strain of Y. pestis leads to attenuation in mice following s.c.